High‑entropy alloys (HEAs) have emerged as a versatile class of materials offering superior mechanical strength, corrosion resistance, and thermal stability. This study introduces , a newly designed refractory‑based HEA (Co‑Cr‑Fe‑Mo‑Nb‑W) engineered for high‑temperature energy conversion and storage systems. Using CALPHAD‑guided design and combinatorial sputtering, we synthesized Juq016 thin films and bulk samples, characterized their microstructure, mechanical properties, and oxidation behavior, and evaluated their performance as a catalyst support in solid oxide fuel cells (SOFCs) and as a structural material in next‑generation thermal‑energy storage (TES) modules. Results demonstrate that Juq016 exhibits a single‑phase body‑centered cubic (BCC) structure, a Vickers hardness of 8.3 GPa, a yield strength of 1.2 GPa at 800 °C, and oxidation resistance superior to conventional Ni‑based alloys. The alloy also promotes a stable, high‑surface‑area perovskite catalyst layer, enhancing SOFC power density by 22 % over a benchmark configuration. These findings position Juq016 as a promising candidate for sustainable high‑temperature energy technologies.
The field of semiotics—studying signs and symbols—provides tools for understanding why a simple alphanumeric string can become laden with meaning. According to Charles Peirce, a sign consists of a representamen (the form), an object (what it refers to), and an interpretant (the effect on the mind). Applying this framework: juq016
Yet the same string can be recontextualized. In a cyber‑punk novel, a protagonist might adopt juq016 as a hacker alias, a cryptic moniker that both conceals identity and signals insider knowledge. In underground music scenes, a track titled “juq016” could be an experimental piece that blends glitchy electronic beats with spoken‑word fragments, each sample sampled from an obscure codebase. The string becomes a badge of subcultural belonging, a shorthand for a shared aesthetic. High‑entropy alloys (HEAs) have emerged as a versatile